Efficient 3’s Complement Circuit for Ternary-ALU

Q4 Engineering

Journal of Integrated Circuits and Systems Pub Date : 2024-03-15 DOI:10.29292/jics.v19i1.750

Aloke Saha, Sudeshna Dutta, Snigdha Dutta, Osman Hossain Siddique, Rimpa Dey, Anup Kumar Das

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引用次数: 0

Abstract

Carrying more information makes the ternary-computation effective in order to reduce the interconnect complexity and hence, ternary computer can be the future alternative to conventional (binary) counterpart. As a consequence the ternary arithmetic has become the centre of choice among circuit/system researcher in recent time. Ternary adder/subtractor is the integral part of Ternary Arithmetic Logic Unit (TALU) and the 3’s complement is used to represent negative ternary number in TALU. This work proposes a new two-step low hardware-cost strategy to converts ternary input into its 3’s complement output. Novel hardware optimization using normal process Enhancement-type Metal Oxide Semiconductor (E-MOS)-transistor is explored and exploited to design proposed 4-trit 3’s complement generator on 32nm standard CMOS technology with 0.9V supply-rail at 27°C temperature using typical MOS-transistor. Unbalanced ternary digit “0”, “1” and “2” are denoted with ground, supply/2 and supply respectively. The T-Spice transient simulations with all possible test patterns validate the working of proposed circuit and the corresponding speed-power characteristic is compared with most recent counterpart. The circuit performance is also evaluated with different load condition. The 4-trit 3’s complement circuit is extended next to propose 16-trit 3’s complement generator and the impact of Process and Environmental variation on the proposed circuit is studied.

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三元-ALU 的高效 3 的补码电路

携带更多的信息使三元运算更加有效，从而降低了互连的复杂性，因此，三元计算机可以成为传统（二进制）计算机的未来替代品。因此，近年来三元运算已成为电路/系统研究人员的首选。三元加法器/减法器是三元算术逻辑单元（TALU）的组成部分，三元补码用于表示 TALU 中的三元负数。这项工作提出了一种新的两步低硬件成本策略，将三元输入转换为 3 的补码输出。利用普通工艺的增强型金属氧化物半导体（E-MOS）晶体管进行了新颖的硬件优化，并利用典型的 MOS 晶体管在 32nm 标准 CMOS 技术上，在 27°C 温度条件下，以 0.9V 电源轨设计出了拟议的 4 三位 3 的补码发生器。不平衡三元数字 "0"、"1 "和 "2 "分别用接地、电源/2 和电源表示。利用所有可能的测试模式进行的 T-Spice 瞬态仿真验证了所提电路的工作原理，并将相应的速度-功率特性与最新的同类电路进行了比较。电路性能还在不同负载条件下进行了评估。接下来，对 4 三位 3 的补码电路进行了扩展，提出了 16 三位 3 的补码发生器，并研究了工艺和环境变化对拟议电路的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Integrated Circuits and Systems Engineering-Electrical and Electronic Engineering

CiteScore

0.90

自引率

0.00%

发文量

期刊介绍： This journal will present state-of-art papers on Integrated Circuits and Systems. It is an effort of both Brazilian Microelectronics Society - SBMicro and Brazilian Computer Society - SBC to create a new scientific journal covering Process and Materials, Device and Characterization, Design, Test and CAD of Integrated Circuits and Systems. The Journal of Integrated Circuits and Systems is published through Special Issues on subjects to be defined by the Editorial Board. Special issues will publish selected papers from both Brazilian Societies annual conferences, SBCCI - Symposium on Integrated Circuits and Systems and SBMicro - Symposium on Microelectronics Technology and Devices.